Method for provisioning and product

ABSTRACT

A method ( 300, 400 ) to provide for provisioning and a product. In one embodiment a processor ( 210 ) receives a pre-configured data image and writes it to a first area ( 221 ) of non-volatile memory ( 220 ) using, for example a first writing mode. Thereafter, for example after a power cycle the processor ( 210 ) determines whether an update to a second area of the non-volatile memory is required, and if so converts a first data item from the first area into a second data item uniquely associated with the product unit and writes the second data item in a second area ( 222 ) using a second writing mode.

FIELD OF THE INVENTION

The present invention relates in general to the provisioning of thememory of consumer products, such as electronic devices, communicationsunits or the like with software.

BACKGROUND OF THE INVENTION

During the manufacturing of relatively complex, software-driven consumerproducts such as communications units, mobile phones, subscriberdevices, or the like, data must be loaded into the product to controloperation and provide, for example, an operating software baseline andother data required for operation. Some data may be common to everyphone produced by a manufacturer, such as the operating software, whileother data, such as mobile service provider network, may be specific toone or a group of phones. Mobile service providers, for example, mayrequire phones programmed with parameters associated with the serviceprovider's particular network and thus groups of phones associated withthe mobile service provider will have many of the same programmingparameters.

In many mobile phone applications, features are already present in aphone and may be controlled, e.g. enabled and/or disabled, almostexclusively through software based on the services which an individualuser or subscriber has paid for. In many service environments such asGlobal System for Mobile communications (GSM) environments, phonesubsidies may be offered to customers by service providers to reduce oreliminate the cost of hardware in exchange for service subscriptionswith the service provider offering the subsidy. Data is often storedwith such subsidized phones to prevent activation or operation with anon-subsidy service provider.

Phone specific data often contains information that, in addition tobeing essential for proper operation of the phone in the serviceenvironment, may be tampered with or otherwise modified in order to gainfree service or gain access to features that would ordinarily beunavailable.

Problems arise however in that loading software, e.g. provisioning aproduct can become time intensive within a production environment whereslightly differing needs among different service providers or customers,network operators, hardware providers or the like must be addressed.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying figures, where like reference numerals refer toidentical or functionally similar elements throughout the separate viewsand which together with the detailed description below are incorporatedin and form part of the specification, serve to further illustratevarious embodiments and to explain various principles and advantages inaccordance with the present invention.

FIG. 1 is a block diagram depicting an exemplary embodiment of a productunit and a programming device arranged for rapid provisioning;

FIG. 2 is a block diagram depicting components of an exemplary productunit suitable for implementing rapid provisioning;

FIG. 3 is a block diagram further depicting components of an exemplaryproduct unit including non-volatile memory areas suitable forimplementing rapid provisioning;

FIG. 4 is a flow chart depicting an exemplary embodiment of a method forproviding rapid provisioning to a product unit;

FIG. 5 is a flow chart further depicting an exemplary embodiment of amethod for providing rapid provisioning to a product unit; and

FIG. 6 is a diagram further depicting an exemplary embodiment of amethod for providing rapid provisioning to a product unit.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

In overview, the present disclosure concerns consumer products,electronic devices such as communications units, and the like and amethod and apparatus for rapid provisioning of such devices or consumerproduct units. Rapid provisioning may be provided from a programmingdevice or fixture coupled to the product unit during a manufacturingprocess associated with the product unit, or alternatively memorydevices may be pre-written in accordance with various exemplary andalternative exemplary embodiments prior to assembly within the productunit. Product units may further be rapidly provisioned in a serviceenvironment while performing software upgrades or when units are beingreconfigured for different customers, including subscribers, wirelessservice providers, or the like. Product units may include wirelesscommunications units often referred to as subscriber devices, such ascellular or mobile phones, two-way radios, messaging devices, personaldigital assistant, personal assignment pads, and personal computersequipped for wireless operation, a cellular handset or device, or thelike, or equivalents thereof provided such units are arranged andconstructed for operation in accordance with the various inventiveconcepts and principles embodied in consumer products, systems,electronic devices or communications units, and methods for providing,initiating, or facilitating rapid provisioning of a product unit asdiscussed and described herein.

The principles and concepts discussed and described may be particularlyapplicable to units, devices, and systems providing or facilitatingvoice communications services or data or messaging services over widearea networks (WANs), such as conventional two way systems and devices,various cellular phone systems including analog and digital cellular,CDMA (code division multiple access) and variants thereof, GSM (GlobalSystem for Mobile communications), GPRS (General Packet Radio System),2.5 G and 3G systems such as UMTS (Universal Mobile TelecommunicationService) systems, integrated digital enhanced networks and variants orevolutions thereof. Principles and concepts described herein may furtherbe applied in devices or systems with short range communicationscapability normally referred to as W-LAN capabilities, such as IEEE802.11, Bluetooth, or Hiper-LAN and the like that preferably utilizeCDMA, frequency hopping, orthogonal frequency division multiplexing, orTDMA access technologies and one or more of various networkingprotocols, such as TCP/IP (Transmission Control Protocol/InternetProtocol), IPX/SPX (Inter-Packet Exchange/Sequential Packet Exchange),Net BIOS (Network Basic Input Output System) or other protocolstructures.

As described in greater detail hereinafter, various inventive principlesare employed to provision a first area of a non-volatile memory area ofa product unit in a rapid fashion with a data image containing dataelements, some of which may be re-written in a secure fashion into asecond area using a slower writing method. In one embodiment an imagehaving a first data type is rapidly written to a first area of thenon-volatile memory, the image including data elements that may besusceptible of being tampered with. Next such data elements that may besusceptible of being tampered with are written into a second area of thenon-volatile memory, using techniques including an encoding process suchas an encryption process and a slower writing process in accordance withvarious exemplary embodiments as will be described in greater detail.Accordingly data elements processed in such a manner and thus theproduct unit associated therewith, may be protected from tampering andmay optionally be disabled, provided these principles or equivalentsthereof are followed.

The instant disclosure is provided to further explain in an enablingfashion the best modes of making and using various embodiments inaccordance with the present invention. The disclosure is further offeredto enhance an understanding and appreciation for the inventiveprinciples and advantages thereof, rather than to limit in any mannerthe invention. The invention is defined solely by the appended claimsincluding any amendments made during the pendency of this applicationand all equivalents of those claims as issued.

It is further understood that the use of relational terms, if any, suchas first and second, top and bottom, and the like are used solely todistinguish one from another entity or action without necessarilyrequiring or implying any actual such relationship or order between suchentities or actions.

Much of the inventive functionality and many of the inventive principlesare best implemented with or in software programs or instructions andintegrated circuits (ICs) such as application specific ICs. It isexpected that one of ordinary skill, notwithstanding possiblysignificant effort and many design choices motivated by, for example,available time, current technology, and economic considerations, whenguided by the concepts and principles disclosed herein will be readilycapable of generating such software instructions and programs and ICswith minimal experimentation. Therefore, in the interest of brevity andminimization of any risk of obscuring the principles and conceptsaccording to the present invention, further discussion of such softwareand ICs, if any, will be limited to the essentials with respect to theprinciples and concepts used by the preferred embodiments.

Referring to FIG. 1, a simplified and representative diagram of aproduct unit and programmer suitable for implementing exemplary methodsof rapid provisioning will be discussed and described. In scenario 100,exemplary product unit 110, which, as described, may include a host ofconsumer products or electronic devices, such as communication units andthe like, and configuration programming device 120, which may be adedicated production or service device having, for example, acommunication link to product unit 110 as the Device Under Test (DUT), aprocessor configured to be at least capable of remotely taking controlof the DUT, loading software there within and otherwise having access toresources of the DUT, e.g. through access to address space within theDUT for data reading and writing and configuration as would beappreciated in the art. Alternately, programming device 120 may be an InCircuit Emulator (ICE) capable of taking control of the DUT as areplacement of the resident processor. As will be understood to one ofskill in the art, programming device 120 may alternatively be a FLASHprogrammer and may be coupled to product unit 110 using communicationsinterface 121 which may be, for example, a JTAG (Joint Test AccessGroup) adapter coupled through an IEEE 1149.1 interface or the like.

In accordance with various exemplary and alternative exemplaryembodiments, programming device 120 may simply communicate to productunit 110 through a serial communications port associated therewith. Manyfactors can be determinative of which programming device 120 is bestsuited to be used, such as the degree of gain in programming speeddesired in the production run associated with making and provisioningproduct unit 110. Another consideration may the capabilities required ofprogramming device 120 in terms of how many separate configurationimages will be stored and loaded on the same model of product unit 110.The access speed of a non-volatile memory area associated with storageof the configuration image for product unit 110, may also bedeterminative of the optimal configuration of hardware and softwareassociated with programming device 120. It will further be appreciatedthat the configuration image may be programmed or otherwise constructedon programming device 120 in advance of programming. The configurationimage may even be copied from a prototype model of product unit 110.

Regardless of how the configuration image is constructed, in accordancewith alternative exemplary embodiments the configuration image may beFLASH programmed into a loose non-volatile memory part at an earlierstage in manufacturing, e.g. a sub-assembly stage, and the programmedpart, e.g. the non-volatile memory, added to the final assembly, e.g.soldered in place within a circuit board associated with product unit110, in a pre-programmed state.

Referring to FIG. 2, a simplified block diagram of exemplary productunit 110 suitable for implementing exemplary methods of rapidprovisioning will be discussed and described. As shown in exemplaryscenario 200, product unit 110 may be embodied as a wirelesscommunication unit and for example, includes various standard componentsthereof including but not limited to processor 210, which may be aconventional processor or a proprietary processor specially configuredfor application within product unit 110, memory 220 which may includeRAM, EEPROM, etc. memory as would be known in the art, transceiver 230which may be a module capable of transmitting and receiving signalsusing antenna 231 over an air interface, user interface 240 which mayinclude a display, a keypad, function buttons and the like. In order tocommunicate information to product unit 110, e.g. for provisioningpurposes, a communication link 211 can be provided to processor 210 as away of establishing communications with, for example, a programmingdevice such as programming device 120 or the like capable of loading aconfiguration image. Alternatively, memory 220 may be directly accessedthrough interface 221 to directly load memory 220 with various contentswhile outside product unit 110, for example, in sub-assemblymanufacture. To facilitate data transfer within product unit 110 betweenmemory 220 and various components, bus 213 can be provided and this caninclude control, address, and data busses connecting all addressablecomponents of product unit 110. For example, transceiver 230 may becoupled to bus 213 via bus interface 232, processor 210 may be coupledto bus 213 via bus interface 212, and user interface 240 may be coupledto bus 213 via bus interface 242. It will be appreciated that, apartfrom the inventive concepts, modifications, and improvements disclosedherein, wireless communications units are generally known. Thus theknown functions and structure of such devices will not be described indetail other than as related to the inventive principles and conceptsdisclosed and discussed below. Note also that the product unit 110embodied in any one of a variety of devices or units discussed above mayhave access or be capable of having access to more than one network.

Referring to FIG. 3 a more detailed block diagram of a preferredembodiment of an exemplary electronic device or product unit 110 will bediscussed and described. As shown in exemplary scenario 300, productunit 110 may be arranged and constructed for rapid provisioning by wayof a first area NVM1 320 and a second area NVM2 330 of non-volatilememory 310. Note that in some instances, the specific functionality ofportions, functional blocks or elements of product unit 110 may dependon the particular access technology and other conventions used by thenetwork providers. The specifics of transmission and reception andrelevant processing are known and therefore any further discussions willbe in generalities that are applicable to typical communicationssystems. However, data elements associated with, for example, the accessnetwork, enabled features, subsidies, user parameters and the like, tothe extent such information may be used as a security element are ofinterest and will be described in greater detail in connection withvarious exemplary embodiments.

Product unit 110 can be coupled to, for example, a programming devicesuch as programming device 120 as previously described, via a link orcommunications interface 211 between the programming device andprocessor 210. As noted, programming device 120 may be a dedicatedproduction device or fixture associated with programming a large numberof product unit 110 in a rapid fashion or may be an ICE or a JTAGprogrammer or other programming device as would be known in the art. Theprogramming device may take control of product unit 110 and load aconfiguration image in rapid fashion, e.g. through a FLASH writingprocess, the configuration image containing elements destined initiallyfor NVM1 320 and optionally including a production software baseline302, e.g. for operating product unit 110. In some embodiments, aprogramming device may first load a “downloader” program into memory220, e.g. in area 303 of RAM 301 which then controls the transfer ofconfiguration image data to a range of specified memory addresses, e.g.associated with NVM1 320. It should be noted that to facilitate loadingof the downloader program, a bootloader 311 can be loaded andpermanently stored in non-volatile memory 310 to initially load thedownloader program into area 303 of RAM 301, e.g. within memory 220. RAM301 may further be used in a normal fashion during operation, e.g. forrun-time uses. Optionally, as noted, a production software baseline orthe like may be loaded with the image and stored in NVM 310, forexample, in area 302 of NVM 310. Otherwise it will be appreciated thatoperating software may reside either within NVM1 320 or may reside in aseparate area of memory 220 such as a ROM area or the like along with,for example, application 224, operating system 225, BIOS 226, and thelike.

It can be seen that NVM1 320 can contain model specific data 321, e.g.configuration parameters common to the model associated with productunit 110 and user data initialized to a factory default state duringproduction such as phone number or the like. Non-volatile memory 310 mayfurther be configured with a second area:

NVM2 330, for containing device specific data in the form of data ortuning data specific to the particular hardware used to constructproduct unit 110 such as transceiver coefficients and other parameterswhich address, for example, unique tolerances specific to the individualhardware components used in the particular instance of product unit 110.NVM2 may further contain device specific data in the form of encrypteddata 331 which, using a unique encryption key stored in a manner whichprevents reading of the actual key even by the processor, for example,within encryption circuit 214 of processor 210, may be created andstored to be uniquely associated with product unit 110. Some deviceunique or specific data, such as the tuning data, can be stored in NVM2330 prior to flashing the device or memory as described herein.

To better understand the inventive concepts and principles embodiedherein, reference will be made to FIG. 4 wherein a flow chart of anexemplary method will be described and discussed. Method 400 will bedescribed in the context of the apparatus of FIG. 1 through FIG. 3 butit should be understood that the method may be practiced by other andsimilar apparatus. Method 400 begins at 401 with a power-up of productunit 110 and an initialization of communication interface 211 at 402.Since, during production, processor 210 contains no application code, atinitialization, processor 210 will be in a wait, or standby state atwhich time a pre-configured image containing the software configurationmay be loaded 403 into NVM 310 and NVM1 320.

One approach to loading the configuration image includes issuing a“TEST” command on communications interface 211 whereupon the processorwill be ready to receive data at a specified address or address range. Aprogramming device coupled to processor 210 over communicationsinterface 211 may further load a “downloader” program which can beresident in either a RAM area associated with processor 210 or aresident RAM device associated with product unit 110, such as RAM 301 ofmemory 220, to facilitate the rapid writing of the configuration imagethereto. Thus using a downloader, a configuration image can be rapidlyflash written to NVM1 320 including first data elements, which, becauseof their relevance to tamper resistance, may also be referred to assecurity elements. Then at 404 after the flash writing procedure theunit is powered off. The next time the unit is powered on 405, in oneembodiment a flag can be checked, as will be described in greater detailhereinafter, to determine whether NVM2 330 requires updating 406, e.g.updating of the security elements stored therein, however it will beappreciated that the presence of the configuration image within NVM1 320can act as a flag. If NVM2 330 needs updating, e.g. the securityelements that are desired do not match those presently stored or perhapsnone are stored in NVM2 330, and the flag is set, then the securityelements, e.g. first data elements, are converted to second dataelements, for example through an encryption process and may further bewritten to NVM2 330 in a second writing mode, e.g. a “flex” writingmode. Note that detecting the presence of the image or relevant portionthereof, or the like, within NVM1 320 can serve as the flag, thusindicating that NVM2 330 needs to be updated. This situation may arisefor the initial in-production writing or flashing of NVM1 320.

Flex writing may be distinguished from the more rapid writing associatedwith flash writing in that flex writing involves issuing a write commandassociated with a particular data element to product unit 110 which isthen written in a manner similar to standard file writing as would beknown in the art. Flex writing in accordance with various exemplaryembodiments preferably uses a file manager, such as Intel® Flash DataIntegrator (Intel® FDI) to manage code, data, and files in a flashmemory, e.g. NVM 1 320 and NVM 2 330. Through the use of an ApplicationProgram Interface (API) FDI supports storage of numerically identifieddata parameters, data streams for voice recordings and multimedia, Javaapplets and native code for direct execution, and ANSI-style files. FDIfurther has a background manager to handle power-loss recovery andwear-leveling of flash data blocks to increase cycling endurance.

In a typical flash memory, all bits are set to a logic one when the partis in an “erased” state and data writing may be performed by settingappropriate bits to zero.

Erasing, as noted, involves setting all bits back to one and ispreferably done on a page basis, where page sizes are large, e.g. 64K or128K pages, relative to, for example, encrypted security elements. Inorder to write to an area, the page must be erased then written to inits entirety. In a flex writing scenario, a relatively small amount ofdata, say several bytes associated with, for example, an encodedsecurity data element plus a pointer can be written through the FDI orlike interface, somewhere within an entire page of NVM2 330. As data iswritten and erased, the FDI or like file manager must maintain a growinglist of pointers to the “fresh” areas of NVM2 330, e.g. fresh areasbeing those areas that can still be written to. When a page has beenfilled through exhaustion of space within NVM2 330 due to the indirectwriting techniques described, data must be consolidated, temporarilystored, such as in a separate page of NVM2 330 and the exhausted page ofNVM2 must be erased in order to support new write operations. Theconsolidated data may then be written back to NVM2 330.

Thus when large amounts of data are being written, the flash writingmode can be much faster than using the flex writing mode for the sameamount of data, particularly when a large number of product units needto be provisioned. However it will be appreciated that by flash writinglarge blocks of data and flex writing other data requiring flex writing,net gains or improvements in per unit programming time may beexperienced, even with the significant time penalties of flex writing.Security elements may thus be written using flex writing in accordancewith various exemplary embodiments described herein.

It will be further appreciated that in accordance with known productunit programming or provisioning scenarios, only a software baseline isflash programmed, for example, into NVM1 320. All customer-specificparameters are written in a flex writing mode into NVM1 320, withsecurity related parameters being flexed into NVM2 330, taking up to 30minutes per unit. In one exemplary scenario for reducing programmingtime, a software baseline plus an image of customer specific data may beflashed into NVM1 320, then a small flex write of NVM2 330 can beperformed with just security related parameters. Such an approach whileimproving over the conventional approach, however could still poseproblems in that two files must be maintained at the production levelhaving customer specific information split there between unlike theconventional or known approach that, while using two files, consolidatedall customer specific data in a single file. It can be appreciated thaterrors may easily be introduced by file mix-ups, e.g. a flash file fromcustomer A and a flex file from customer B. In accordance with variousexemplary embodiments described herein, all information can be containedin a single file for record purposes and the like, e.g. a flash file orimage that is flash written for provisioning purposes.

Thus, in accordance with various exemplary embodiments described herein,parameters are flashed into a first area of non-volatile memory in atime on the order of several tens of seconds, by device 120 in aproduction process and then the product unit 110 is powered off.Re-powering the product unit 110 at 405 invokes a process within theproduct unit 10 whereby security parameters included with the image areflex written in an encrypted mode to a second area of non-volatilememory. Even though the flex writing process is slower due to pointermanagement by a file manager or FDI process an the like, it can becarried out by the product unit 110 on a per-unit basis once flashwriting of all the product parameters has been completed. As will bediscussed further below this is particularly advantageous when a unitspecific encryption key is used and especially so if the key is noteasily obtained.

The data element may further be encoded or encrypted using, for example,128-bit DES (Data Encryption Standard) encryption using a unique 128-bitencryption key stored in product unit 110 in, for example, encryptioncircuit 214. Note that the result of this encryption is data or a seconddate element that is unique for each product unit. It will beappreciated that the encryption circuit 214 in certain embodiments ispermanently configured with an encryption key in a manner such that theactual value of the key cannot be accessed by anyone including processor210, or can not be modified or otherwise tampered with. Data to beencrypted is input to the encryption circuit 214 which may include, forexample, the calculation and addition of a CRC value to form anintermediate value including a first data element and a CRC appendedthereto. A key or encryption key, such as a 128-bit DES key can be usedto encrypt the intermediate value which is output therefrom as encodedor encrypted second data element whereupon it can be stored, forexample, in NVM2 330. When decrypting using encryption circuit 214, theencrypted second data is decrypted using the 128-bit DES key to theintermediate value, a CRC is generated on the contents representing thefirst data element and compared with the decrypted CRC that wasappended. If the values do not match, an error can be detected, whichcould be strongly indicative of tampering. Once flash writing of NVM1320 has been accomplished power can be removed and upon re-powering ofproduct unit 110, flex writing of NVM2 330 can be accomplished ifnecessary. The product unit 110 is then operated in a normal fashion.

Reference will now be made to FIG. 5 wherein a more detailed flow chartof an exemplary method will be described and discussed. Method 500begins at 501 with a power-up of product unit 110. At 502, a test ismade to determine whether an update to NVM2 330 is required. If so, atest may be made at 503 to determine whether in accordance with variouslocking procedures, product unit 110 is security locked, e.g. simlocked,subsidy locked, or the like.

It will be appreciated by those skilled in the art that locking is atamper prevention mechanism to permanently or semipermanently “lock” theoperation of the phone to certain features or other programmedparameters which have been purchased or are otherwise part of a user'sservice agreement with, for example, a particular network operator orservice provider. A product may be SIM-locked whereby product unit 110,such as a communications unit or mobile phone is locked to a particularSIM card. If product unit 110 is simlocked to a SIM no other SIM may beused or alternatively, only SIMs from a particular service provider ornetwork operator may be used in the phone. SIM-lock may also be referredto as product lock, feature lock, subscription lock, subsidy lock,service provider (SP) lock or network lock. In the case of a network, SPlock, operator lock or the like, product unit 110 is locked to anoperator, thus any SIM from the operator may be used therein, e.g. whenswitching between various service contracts and prepaid calling asdesired. However, a switch may not be made to a different operator sincea foreign SIM associated with the new operator would not be useable,e.g. due to the lock. Product 110 may further be locked to a code, whichcode could be used in a variety of locking scenarios whereby a code maybe requested and entered to gain access to certain lock relatedoperations. Once NVM2 330 is written, a subsequent failure in matchinglock parameters may indicate that a foreign SIM has been inserted intoproduct unit 110, and operations may be inhibited unless, for example,an unlock password is entered. In accordance with various exemplaryembodiments described herein, security related data elements may furtherbe checked for tampering if contents from NVM2 330, specificallyencrypted data 331 do not decrypt in a proper fashion. Failure todecrypt will preferably result in disabling of product unit 110 since adecryption failure indicates tampering. Problems arise however in thatSIM-lock may be removed allowing any SIM card, depending on phone model,to be inserted therein to allow the phone to be used in a differentoperating environment or foreign networks and in some cases free ofcharges. Such breaking of simlock is particularly troublesome where oneservice provider subsidizes all or part of a phone's cost only to havethe customer break the simlock or subsidy lock and use the phone in adifferent network associated with another service provider, e.g. onewith a cheaper service plan rate. In such subsidy offerings, the cost ofthe phone is generally offset by various charges accrued over the lifeof the plan. If a subsidized phone is tampered with and used in adifferent service environment, not only is the cost of the phone lostbut the revenues from the service plan are lost as well. Thus variousexemplary embodiments of inventive concepts described herein may be usedto prevent tampering with simlocked parameters thus adding an additionalor alternative layer of tamper protection by encrypting the lockparameters with a device specific, 128-bit encryption key, located in anunreadable manner in encryption circuit 214 of processor 210 asdescribed herein above and storing them in area 331 of NVM2 330.

In accordance with various alternative exemplary embodiments, a scenariocan be envisioned whereby a product unit 110 is manufactured andprovisioned with an extensive portfolio of resident features including,for example, basic features which can be enabled during production, andadditional features which may be arranged as feature tiers or individualfeatures to be purchased and configured at a point of sale ordistribution. It should be noted that in a minor departure from theconcepts described herein, an update flag may be stored in a pendingstatus such that it is not cleared until the final feature set isdetermined at the point of sale or distribution. In such a way, thegeneric model of product unit 110 may be generously stocked as a singlemodel with features being enabled depending on the requirements of thecustomer and willingness of the customer to pay the price for theadditional features. In such a scenario, a fixture or programming device120 located at the point of sale may be used to enable the features, andset a flag indicating that, for example, NVM2 330 requires an update.The feature data may be arranged, encrypted and written as securityelements to NVM 2 330 in a manner as previously described and to bedescribed in greater detail hereinafter. Product unit 110 may then, as afinal measure be locked and further writing prevented, and the updatestatus may be reset to updated, e.g. no update required.

Returning to FIG. 5, if test 503 determines that product unit 110 andthus, for example, NVM2 330 is not security locked, then first dataelements, included, for example, with a configuration image rapidlyflash written into NVM1 320 in accordance with an earlier process, maybe converted 504 into second data elements and stored in NVM2 330. Uponthe first re-powering after flashing or otherwise modifying NVM1 is anmanner that needs to be reflected in NVM2, first data elements may beconverted, e.g. encrypted in the manner described herein above, usingthe 128-bit key in encryption circuit 214 and a 128-bit DES algorithmstored, for example, in encryption circuit 214 or a different area ofthe non-volatile memory and run on processor 210, or stored and run onprogramming device 120, or the like. In either case, the 128-bitencryption key associated with encryption circuit 214 is preferablyunique to product unit 110 and thus will be used in any conversion orencryption step regardless of whether performed using processor 210 oran external processor or programming device. In accordance withpreferred exemplary embodiments, encryption circuit 214 may be embodiedas a cell within processor 210, which itself may be a dedicated,proprietary, or custom processor, IC, ASIC, or the like as would beappreciated by one of ordinary skill in the art. Further it will beappreciated that the encryption circuit may alternatively be an encoderor may use a different kind of encryption, preferably with no or limitedaccess to the key, where the resulting data is tied specifically toproduct unit 110, either by using, for example, the serial number orother unique and device-specific identifier in the encoding orencryption process. After conversion, converted or encrypted first dataelements may be stored into area 331 of NVM2 330 using flex writing asdescribed above, which is a slower writing process. It will beappreciated that encryption may be incorporated as part of the flexwriting process or may be an intermediate step without departing fromthe scope of the disclosure. Once NVM2 330 has been updated, an updateflag may be reset at 505 to reflect that the contents of NVM2 330 nowreflect the present security parameters, or alternatively theconfiguration image, e.g. the contents of NVM1 320 may be erased or thelike, and the power-up initialization may proceed at 508.

If, however, test 503 determines that product unit 110 is securitylocked, then a second test may be made at 506 to determine whether theencrypted contents of NVM2 330 are valid, e.g. the same as the firstdata elements previously written to NVM1 320, using, for example, adecryption process described herein after. If the elements are the same,then the update flag can be reset in 505, or alternatively NVM1 320 maybe erased, indicating that an update is not necessary. If the elementsare not the same, then a configuration error is present at 507 andproduct unit 110 may be inoperative until, for example, a unlockpassword is entered, or alternatively, product unit 110 may bepermanently disabled if tampering is detected.

A more detailed view of an exemplary embodiment shown in FIG. 6 will nowbe described and discussed. In scenario 600, while several alternategroupings, e.g. 630, 640, and 650 are shown for carrying out exemplaryfunctions associated with rapid provisioning of product unit 110,specifically NVM1 320 and NVM2 330 thereof, the process is virtually thesame. As shown, for example in grouping 630, processor 610 and flashwrite process 614 may be resident together with NVM1 320 and NVM2 330within, for example, product unit 110 while linked to, for example, aprogramming device through communications link 612. Alternatively, asshown in alternate grouping 640, processor 610 and flash write processmay reside together outside product unit 110 within, say, a programmingdevice such as an ICE or dedicated jig or fixture as described above,and may remotely gain control of product unit 110 for flash writing ofNVM 1 320 and flex writing of NVM 2 330 in the manner previouslydescribed. Still further, alternate grouping 650, may represent anon-volatile memory device including NVM 1 320 and NVM 2 330 programmedindependently of product unit 110 and then assembled into product unit110 fully programmed using an external programming device having, forexample, at least processor 610 and flash writing process 614.

Thus in accordance with any of the above alternative groupings,configuration image 620 may be constructed on an external programmingfixture by piecing together various binary representations of softwareand data required to form a complete software baseline includingsecurity elements. It will be appreciated in the art that theconstruction of configuration image 620 may be accomplished in amultitude of ways including copying an image from the non-volatilememory of another product of the same model and with the identicalparameters as those desired for product unit 110. In any case, it shouldbe noted that configuration image 620 may preferably contain area 621for non-security related data such as software baseline, model specificdata, user data and the like, while area 622 of configuration image 620may contain security related data elements or first data elements.Alternatively, first data elements may be located at various placeswithin configuration image 620 requiring a degree of intelligence in thewriting process, e.g. to know which elements should be encrypted toprevent tampering and the location of such elements within configurationimage 620 and eventually NVM1 320. In a first part 601 of a process ofrapid provisioning, configuration image may be loaded into a memory areaassociated with a flash writing process 614. Such an area may be a RAMarea located within product unit 110 or processor 210 or 610 or may beotherwise accessible for storage of all or part of configuration image620 for the purposes of performing flash writing thereof. In second part602, configuration image 620 may be flash written to NVM1 320 to includemodel specific data 321, user data 322 and an update flag 323,alternately, the presence of configuration image 620 as written to NVM1320 may serve as a flag or be indicative of the need for an update. In athird part 603, update flag 323 or, alternatively, the presence ofconfiguration image 620 and/or the contents thereof, may be checked todetermine whether an update is required which in the case of aproduction state provisioning, will almost certainly be set to show thatupdating is required. One instance, which could be envisioned where anupdate would not be necessary, would be a flash write of the softwarebaseline only; security elements should not be affected thereby. Upondetermining that an update is required in 603, a fourth part may beperformed in 604, which may be considered as an intermediate stepinvolving the reading of security elements or first data elements fromNVM 1 320, converting the first data elements by encrypting them inencryption circuit 633 to form second data elements, and flex writingthe second data elements in 605 to area 331 of NVM 2. Note that thewriting to NVM 2 area 330 is ordinarily accomplished, for example, withthe first power on cycle of the product unit after the flash writing orother modification to NVM 1 320.

The apparatus, processes, and systems discussed above and the inventiveprinciples thereof are intended to and can alleviate problems, such astampering, and programming delays caused by present approaches toprovisioning product units as well as offer a novel and advantageousmethodology for rapid provisioning and tamper resistance/detection.Using the principles of, for example, reading first data elements suchas security elements from a first area of a non-volatile memory,converting the first data elements using, for example, 128-bit DESencryption to second data elements, and writing the second data elementsto a second area of non-volatile memory will facilitate a costeffective, efficient, and flexible means for provisioning and tamperproofing product units which otherwise are delayed in production bylengthy programming procedures and which remain vulnerable to tamperingto defeat service agreements and avoid charges.

Furthermore the concepts and principles disclosed and discussed forrapid provisioning will provide enhanced security since a potentialhacker or tamperer while possibly being able to change data in one areaof non-volatile memory, will be defeated by the presence of an encryptedversion of security data in a second area of non-volatile memory. Aswill be appreciated in view of the exemplary encryption methodsdescribed herein, decryption may be performed by running a decryption orreverse encryption process on the contents of a secure storage area ofnon-volatile memory using an embedded key, which is preferably notcapable of being known. The decrypted contents preferably include a dataitem plus an appended CRC. A new CRC may be generated on the decrypteddata item to generate a new CRC which should match the decrypted CRC. Ifthe CRC values match, it can be presumed that the data item has not beentampered with. If the CRC values do not match, then it can be presumedthat an error has occurred or that the data item has been tampered with.

In accordance with an alternative exemplary embodiment, improperreconciliation between the encrypted security data stored, for example,in one area of non-volatile memory and first data stored in another areaof non-volatile memory may be used to permanently or semi-permanentlyinhibit further functioning of the product unit. It is expected that oneof ordinary skill given the above described principles, concepts, andexamples will be able to implement other alternative procedures offeringrapid provisioning and tamper resistance of product units. It isanticipated that the claims below cover many such other examples.

This disclosure is intended to explain how to fashion and use variousembodiments in accordance with the invention rather than to limit thetrue, intended, and fair scope and spirit thereof. The foregoingdescription is not intended to be exhaustive or to limit the inventionto the precise form disclosed. Modifications or variations are possiblein light of the above teachings. The embodiment(s) was chosen anddescribed to provide the best illustration of the principles of theinvention and its practical application, and to enable one of ordinaryskill in the art to utilize the invention in various embodiments andwith various modifications as are suited to the particular usecontemplated. All such modifications and variations are within the scopeof the invention as determined by the appended claims, as may be amendedduring the pendency of this application for patent, and all equivalentsthereof, when interpreted in accordance with the breadth to which theyare fairly, legally, and equitably entitled.

1. A method for provisioning a product unit having a non-volatilestorage medium, the method comprising: reading at least a first dataitem of a pre-configured data image from a first area of thenon-volatile storage medium; converting the at least first data item toform a second data item uniquely associated with the product unit; andstoring the second data item to a second area of the non-volatilestorage medium using a first writing mode.
 2. A method according toclaim 1, further comprising writing the pre-configured data image to thefirst area of the non-volatile storage medium using a second writingmode.
 3. A method according to claim 2, wherein the first writing modeis slower than the second writing mode.
 4. A method according to claim2, wherein the second writing mode includes a flash writing mode whereinthe pre-configured data image is written therewith.
 5. A methodaccording to claim 1, further comprising setting a flag associated withthe pre-configured data image and stored in the first area to a valueindicating that an update of the second data item into the second areahas been performed and storing the updated flag in the first area.
 6. Amethod according to claim 1, further comprising checking a state of aflag associated with the pre-configured data image and stored in thefirst area to determine whether an update of the encoded second dataitem into the second area has been performed.
 7. A method according toclaim 6, wherein the checking the state is performed prior to theconverting and the converting is performed only if the checkingdetermines that the update has not been performed.
 8. A method accordingto claim 1, wherein the first writing mode includes a flex writing mode.9. A method according to claim 1, wherein the converting furtherincludes: encrypting the first data item to form an encrypted seconddata item.
 10. A method according to claim 1, wherein the at least firstdata item includes one of: one or more network parameters, one or moresubsidy parameters, one or more service provider parameters, one or morefeature parameters, and one or more code parameters.
 11. A method forprovisioning a product unit having a non-volatile storage medium, themethod comprising: reading a flag in a first area of the non-volatilestorage medium to determine whether an update of a second area of thenon-volatile storage medium has been performed; and converting, if theupdate has not been performed, a first data item from the first areainto a second data item uniquely associated with the product unit andwriting the second data item in the second area of the non-volatilestorage medium using a second writing mode.
 12. A method according toclaim 11, wherein the first area of the non-volatile storage medium iswritten with a pre-configured data image using a first writing mode, thepre-configured data image containing at least the first data item andthe flag.
 13. A method according to claim 11, further including settingthe flag to a value indicating that an update of the second data iteminto the second area has been performed.
 14. A method according to claim11, wherein the first writing mode is faster than the second writingmode.
 15. A method according to claim 11, wherein the first writing modeincludes a flash writing mode wherein the entire pre-configured dataimage is written therewith.
 16. A method according to claim 11, whereinthe second writing mode includes a flex writing mode.
 17. A methodaccording to claim 11, wherein the converting further includes:generating an intermediate value associated with the first data item,the intermediate value including the first data item and a firstappended value; and encrypting the intermediate value to form the seconddata item.
 18. A product unit arranged and constructed for provisioning,the product unit comprising: a processor; and a non-volatile memorycoupled to the processor, the non-volatile memory having a first areaand a second area, the processor configured to: check a flag associatedwith a pre-configured data image stored in the first area to determinewhether an update to the second area of the non-volatile memory isrequired, and when an update is required, convert a first data item fromthe first area into a second data item uniquely associated with theproduct unit and write the second data item in the second area of thenon-volatile storage using a second writing mode.
 19. A product unitaccording to claim 18, wherein the processor is further configured to:receive the pre-configured data image and write the pre-configured dataimage to the first area of the non-volatile memory using a first writingmode.
 20. A product unit according to claim 19, wherein the firstwriting mode is faster than the second writing mode.
 21. A product unitaccording to claim 18, wherein the processor is further configured toset the flag to a value indicating that an update of the second area hasbeen performed.
 22. A product unit according to claim 18, wherein afirst writing mode includes a flash writing mode wherein thepre-configured data image is written to the first area.
 23. A productunit according to claim 18, wherein the second writing mode includes aflex writing mode.
 24. A product unit according to claim 18, furthercomprising an encryption circuit uniquely associated with the productunit, and wherein the processor, in converting, is further configured toencrypt the first data item with the encryption circuit to form thesecond data item.
 25. The product unit of claim 24 further comprising awireless communications unit wherein the encryption circuit is furtherutilized to decrypt the second data item to facilitate detectingtampering of the second data item.